Downhole corrosion, erosion, scale and deposit monitoring system

ABSTRACT

A tool for monitoring conditions within a subterranean well includes a first body segment, the first body segment being an elongated member with an axial protrusion having a reduced outer diameter. A second body segment is sized for mating with the first body segment. A metal specimen circumscribes the axial protrusion of the first body segment so that an outer diameter surface of the metal specimen defines an outer diameter of the tool. A connection assembly releasably secures the first body segment to the second body segment.

CROSS REFERENCE TO RELATED APPLICATION

This application is a divisional of and claims priority to and thebenefit of co-pending U.S. Nonprovisional application Ser. No.15/423,158, filed Feb. 2, 2017, titled “Downhole Corrosion, Erosion,Scale And Deposit Monitoring System,” which claims priority to and thebenefit of U.S. Provisional Application Ser. No. 62/293,021, filed Feb.9, 2016, titled “Downhole Corrosion, Erosion, Scale And DepositMonitoring System,” the full disclosure of each which is herebyincorporated herein by reference in its entirety for all purposes.

BACKGROUND OF THE DISCLOSURE 1. Field of the Disclosure

The disclosure relates generally to downhole monitoring of wellconditions, and more particularly to quantifying corrosion, erosion,scale and deposit formation in within a subterranean well.

2. Description of the Related Art

Ageing hydrocarbon development and production wells can developcorrosion, erosion and scale that give rise to a maintenance issues foroperators. Corrosion, erosion and scale can increase operating costs andlead to the shutdown of the wells. In order to determine the most costeffective methods for treating the wells and minimizing downholecorrosion, erosion and scale, the monitoring systems and methods fordetermining the extent and nature of the corrosion, erosion and scaleare used.

Current systems and methods of monitoring the corrosion, erosion andscale within a wellbore can include a tool that has a test coupon thatis shielded from the direct flow of fluids within the well and redirectsthe flow of fluid over the test piece so that the flow across the testcoupon has been disturbed before reaching the test coupon.

SUMMARY OF THE DISCLOSURE

Embodiments disclosed herein describe systems and methods for monitoringconditions within a subterranean well. Embodiments of this disclosureinclude a metal specimen that is placed on the outside of the downholesystem assembly to more closely simulate the corrosion, erosion andscaling conditions, as well as the flow regimes in oil and gas wells.Features of this disclosure include the sealing and isolation of partscontacting the metal specimen, tight spacing between the metal specimenand tool body as well as the between the tool body parts, and a largesurface area of the metal specimen that is exposed directly to the flowregime for gathering downhole corrosion, erosion, scale, and depositdata.

In an embodiment of this disclosure, a tool for monitoring conditionswithin a subterranean well includes a first body segment, the first bodysegment being an elongated member with an axial protrusion having areduced outer diameter. A second body segment is sized for mating withthe first body segment. A metal specimen circumscribes the axialprotrusion of the first body segment so that an outer diameter surfaceof the metal specimen defines an outer diameter of the tool. Aconnection assembly releasably secures the first body segment to thesecond body segment.

In alternate embodiments, the tool can further include an annularshoulder at an end of the axial protrusion, and the metal specimen canbe located between the annular shoulder and the second body segment. Theconnection assembly can include a threaded member extending between thefirst body segment and the second body segment. A mating assembly can belocated at each end of the metal specimen and can separate the metalspecimen from the first body segment and from the second body segment. Amating assembly can be located between the first body segment and thesecond body segment.

In other alternate embodiments, the tool can include an outer connectionin one of the first body segment and the second body segment, the outerconnection sized to engage an intervention member that is operable tosuspend the monitoring tool within the subterranean well. The metalspecimen can circumscribe both the first body segment and the secondbody segment. The outer diameter surface of the metal specimen can beflush with an outer diameter of at least one of the first body segmentand the second body segment.

In an alternate embodiment of this disclosure, a system for monitoringconditions within a subterranean well includes a monitoring tool havinga first body segment releasably secured to a second body segment, thefirst body segment having an axial protrusion with a reduced outerdiameter. A metal specimen circumscribes the axial protrusion so that anouter diameter surface of the metal specimen defines an outer diameterof the tool. An outer connection is located in one of the first bodysegment and the second body segment. An intervention member is connectedto the outer connection, the intervention member having a grippingmember moveable between a retracted position and an extended position,wherein when the gripping member is in the extended position, theintervention member is operable to suspend the monitoring tool withinthe subterranean well.

In alternate embodiments, the intervention member can include a shockabsorber. The monitoring tool can be shaped so that the outer diametersurface of the metal specimen is located in a direct undisturbed flow offluids through the subterranean well when the monitoring tool is loweredwithin the subterranean well. A mating assembly can be located at eachend of the metal specimen isolating the metal specimen from directcontact with the first body segment and the second body segment. Themating assembly can be formed of a non-metallic and electricallyisolating material.

In yet another alternate embodiment of this disclosure, a method formonitoring conditions within a subterranean well includes providing amonitoring tool having a first body segment, the first body segmentbeing an elongated member with an axial protrusion having a reducedouter diameter, and a second body segment sized for mating with thefirst body segment. The axial protrusion of the first body segment canbe circumscribed with a metal specimen so that an outer diameter surfaceof the metal specimen defines an outer diameter of the monitoring tool.The first body segment can be releasably secured to the second bodysegment. An intervention member can be secured to an outer connection ofone of the first body segment and the second body segment. Themonitoring tool can be lowered into the subterranean well with theintervention member.

In alternate embodiments, before circumscribing the axial protrusion ofthe first body segment with the metal specimen, at least one of a weightand profile of the metal specimen can be measured. The monitoring toolcan be raised out of the subterranean well with the intervention memberand at least one of a weight and profile of the metal specimen can bemeasured. After raising the monitoring tool out of the subterranean wellwith the intervention member and measuring a feature of the metalspecimen, a treatment of the subterranean well can be optimized based onthe measurement of the feature, the treatment being one of a scaletreatment or a corrosion treatment.

In other alternate embodiments, the monitoring tool can be located in aflow of fluids through the subterranean well so that the outer diametersurface of the metal specimen is located in a direct undisturbed flow ofthe fluids through the subterranean well. A gripping member of theintervention member can be moved to an extended position so that thegripping member engages an inner diameter surface of the subterraneanwell and supports the monitoring tool within the subterranean well. Oneor more additional monitoring tools can be secured to the outerconnection before lowering the monitoring tool into the subterraneanwell. A composition of the metal specimen of each monitoring tool can bedifferent from the composition of the metal specimen of other monitoringtools.

BRIEF DESCRIPTION OF THE DRAWINGS

So that the manner in which the above-recited features, aspects andadvantages of the embodiments of this disclosure, as well as others thatwill become apparent, are attained and can be understood in detail, amore particular description of the disclosure briefly summarized abovemay be had by reference to the embodiments thereof that are illustratedin the drawings that form a part of this specification. It is to benoted, however, that the appended drawings illustrate only preferredembodiments of the disclosure and are, therefore, not to be consideredlimiting of the disclosure's scope, for the disclosure may admit toother equally effective embodiments.

FIG. 1 is a schematic view of a monitoring system of a subterraneanwell, in accordance with an embodiment of this disclosure

FIG. 2, is a perspective view of a monitoring tool, in accordance withan embodiment of this disclosure.

FIG. 3, is a section view of a portion of the monitoring tool of FIG. 2.

FIG. 4, is a perspective view of a monitoring tool, in accordance withan embodiment of this disclosure.

FIG. 5, is a cross sectional view of the monitoring tool of FIG. 4.

FIG. 6, is a perspective view of a monitoring tool, in accordance withan embodiment of this disclosure.

FIG. 7 is a side view of a monitoring tool, in accordance with anembodiment of this disclosure.

FIG. 8 is a section view of the monitoring tool of FIG. 7, viewed alongthe section line shown in FIG. 7.

DETAILED DESCRIPTION

Embodiments of the present disclosure will now be described more fullyhereinafter with reference to the accompanying drawings which illustrateembodiments of the disclosure. Systems and methods of this disclosuremay, however, be embodied in many different forms and should not beconstrued as limited to the illustrated embodiments set forth herein.Rather, these embodiments are provided so that this disclosure will bethorough and complete, and will fully convey the scope of the disclosureto those skilled in the art. Like numbers refer to like elementsthroughout, and the prime notation, if used, indicates similar elementsin alternative embodiments or positions.

In the following discussion, numerous specific details are set forth toprovide a thorough understanding of the present disclosure. However, itwill be obvious to those skilled in the art that embodiments of thepresent disclosure can be practiced without such specific details.Additionally, for the most part, details concerning well drilling,reservoir testing, well completion and the like have been omittedinasmuch as such details are not considered necessary to obtain acomplete understanding of the present disclosure, and are considered tobe within the skills of persons skilled in the relevant art.

Looking at FIG. 1, a hydrocarbon development and production operationcan include subterranean well 10. Subterranean well 10 has wellbore 12that extends from a wellhead assembly (not shown). The wellhead assemblysits atop subterranean well 10 to manage fluids flowing into and out ofsubterranean well 10. Subterranean well 10 can be used to produce oil,gas, and can be used to inject and produce other fluids that areassociated with oil and gas production. A communication and controlmodule can be used to monitor, manage, and control the operations atsubterranean well 10. Monitoring tool 16 can be used to determinecertain conditions within subterranean well 10, such as quantifyingcorrosion, erosion, scale and deposit formation in within subterraneanwell 10, as disclosed herein.

Looking at FIGS. 3 and 8, monitoring tool 16 can include first bodysegment 18 and second body segment 20. First body segment 18 can be anelongated member with an axis Ax. First body segment 18 can be, as anexample, a generally cylindrical shaped member. First body segment 18can have base body portion 22 and axial protrusion 24 with a reducedouter diameter. Annular shoulder 26 is located at a transition betweenbase body portion 22 and axial protrusion 24. Annular shoulder 26 canhave a surface that is generally normal to axis Ax.

Second body segment 20 can also be an elongated member. Second bodysegment 20 can also have a generally cylindrical shape. Looking at theexample of FIG. 3, second body segment 20 can have the same or similarshape as first body segment 18. In such an embodiment the axialprotrusion of each axial protrusion 24 will be proximate to each otherwhen first body segment 18 is releasably secured to second body segment20. In an alternate example of FIG. 8, second body segment 20 can haveinner recess 28 that is sized for mating with axial protrusion 24.

Connection assembly 30 can releasably secure first body segment 18 tosecond body segment 20. In the example embodiment of FIGS. 3-4,connection assembly 30 can include a central bore 29 that extends alongaxis Ax through both first body segment 18 and second body segment 20.Retaining member 31 extends through central bore 29 and can releasablysecure first body segment to second body segment. As an example,retaining member 31 can be a threaded member that threads into firstbody segment 18 or second body segment 20 or can have a nut that isthreaded onto retaining member 31.

In the alternate example embodiment of FIG. 8, connection assembly 30includes outer threads 32 on an outer surface of axial protrusion 24 andmating threads 34 on an inner surface of inner recess 28. Axialprotrusion 24 can be threaded into inner recess 28 in order toreleasably secure first body segment 18 to second body segment 20. Inorder to facilitate the threading of axial protrusion 24 into innerrecess 28, tool profile 33 can be provided on an outer diameter or endsurface of first body segment 18 and second body segment 20. A hand toolcan be used to grip tool profile 33 to rotate one of first body segment18 and second body segment 20 relative to the other.

In order to prevent first body segment 18 from being separated fromsecond body segment 20, connection assembly 30 can also include setscrew 36. Set screw 36 can extend between first body segment 18 andsecond body segment 20, preventing relative rotational or relative axialmovement between first body segment 18 and second body segment 20. Thealignment of set screw 36 between first body segment 18 and second bodysegment 20 also ensures that first body segment 18 and second bodysegment 20 have been properly engaged. An operator can rotate one offirst body segment 18 and second body segment 20 relative to the otheruntil the opening or recess within first body segment 18 and second bodysegment 20 to accommodated set screw 36 align, and such alignment canensure full sealing engagement between the components of monitoring tool16.

Monitoring tool 16 also includes metal specimen 38. Metal specimen 38can circumscribe axial protrusion 24 of first body segment 18. Metalspecimen 38 can be, for example, a ring shaped member. Metal specimen 38is located on an outermost external surface of first body segment 18 sothat metal specimen 38 defines an outer diameter of monitoring tool 16.In embodiments of this disclosure, metal specimen 38 has an outerdiameter that is flush with the outer diameter of first body segment 18and second body segment 20. In such an embodiment, there will be minimaldisruption to the flow of fluid over metal specimen 38 and a mostaccurate estimation of the flow can be obtained. In alternateembodiments, the outer diameter of metal specimen 38 can be slightlyrecessed relating to the outer diameter of first body segment 18 andsecond body segment 20. In such an embodiment, the outer diametersurface of metal specimen 38 will be less than an outer diameter of atleast one of first body segment 18 and second body segment 20. With aslightly recessed outer diameter, metal specimen 38 can be raised andlowered within wellbore 12 with a reduced chance of causing any damageto metal specimen 38 or otherwise contacting metal specimen 38 withouter members within wellbore 12 or any wellhead assembly located abovewellbore 12.

Metal specimen 38 can have an axial length of a number of inches. As anexample, metal specimen 38 can have an axial length of one quarter tofive inches and in an alternate embodiment, can have an axial length ofone inch. In certain embodiments, metal specimen 38 can be sufficientlylarge in size so that erosion, corrosion, and scale conditions to whichmetal specimen 38 is subjected accurately reflects actual erosion,corrosion, and scale to which the components of subterranean well 10 aresubjected. A smaller coupon of some current designs are instead of asize that the coupon can be exposed to such little area of flow that theconditions within subterranean well 10 cannot be accurately extrapolatedfrom the results.

Each metal specimen 38 can be formed of a of metallic materials that hasa composition that is useful for modeling the corrosion, erosion andscaling conditions and flow regimes within wellbore 12. As an example,metal specimen 38 can be in the range of a mild steel to a corrosionresistant alloys, and combinations thereof. In certain embodiments wheremore than one monitoring tool 16 are used together, the composition ofmetal specimen 38 of each monitoring tool 16 can be different from thecomposition of metal specimen 38 of each other monitoring tool.

Some current metal coupon downhole systems are designed with the metalspecimens or coupons enclosed within a tool body or shielded from fluidflow. In such an existing design fluid has to travel through slits orpast certain obstructions before contacting the corrosion coupon. Thesemetal specimens and coupons would therefore not be subjected to normal,direct and undisturbed flow of fluid through the wellbore and maytherefore not provide results that are representative of the actualsystem conditions.

Because metal specimen 38 of the current application defines an outerdiameter of monitoring tool 16, metal specimen 38 is subjected to directundisturbed flow of fluids through subterranean well 10 when monitoringtool 16 is lowered within subterranean well 10. Therefore metal specimen38 can be used to closely simulate the corrosion, erosion and scalingconditions and flow regimes within wellbore 12, under typical systemconditions. This can be especially important in gas wells where the flowregime is typically annular or is an annular mist where metal specimen38 is exposed to the fluid flow. Some current test coupon systems areineffectual in wells with low levels of fluid since the coupon islocated within a member that shields the coupon from direct flow and maybe exposed to insufficient flow levels to obtain accurate results.Embodiments of this disclosure are instead particularly well suited tohigh pressure, high temperature wells with low fluid content travelingat high velocity, and in wells with low levels of water being produced.

Metal specimen 38 can be located between annular shoulder 26 and end 40of second body segment 20. Metal specimen 38 can be isolated orseparated from first body segment 18 and second body segment 20, and canbe sealed from first body segment 18 and second body segment 20 withmating assemblies. The mating assemblies can provide a pressure barrierso that as monitoring tool 16 so that as monitoring tool 16 is movedfrom atmospheric pressure conditions to high pressure conditions withinwellbore 12, the mating assembly will provide sufficient sealing toprevent the high pressure from passing between the components ofmonitoring tool 16. In this way, the mating assembly will allowmonitoring tool 16 to act as a pressure vessel with the interior ofmonitoring tool 16 being maintained at atmospheric pressure while theexterior of monitoring tool 16 is exposed to high pressures withinwellbore 12. As connection assembly 30 is made up, the seals of themating assemblies can be energized to form the required seals betweenthe components of monitoring tool 16.

The mating assemblies can include seals 44, 46, 48, spacers 42, 43, or acombination of seals and spacers. Metal specimen 38 can be electricallyisolated from direct contact with first body segment 18 and second bodysegment 20 by spacers and seals that are non-metallic and that canwithstand high temperatures and high pressures with deep downholeapplications, such as, for example, conditions that exist within awellbore 12 that is in the range of 10,000-15,000 feet deep. Inalternate embodiments wellbore 12 can be less than 10,000 feet or evengreater than 15,000 feet deep.

Looking at FIG. 4, the mating assembly can include first body seal 44can be located between first body segment 18 and metal specimen 38.There can be a first body seal 44 on each side of spacer 42 so that nofluids can pass between first body segment 18 and metal specimen 38.First body seal 44 can be a ring shaped member that sits partiallywithin a groove of first body segment 18, spacer 42 or metal specimen38, as applicable. Alternately, other known sealing means can be used.

The mating assembly can also include second body seal 46 can be locatedbetween second body segment 20 and metal specimen 38. There can be asecond body seal 46 on each side of spacer 42 so that no fluids can passbetween second body segment 20 and metal specimen 38. Second body seal46 can be a ring shaped member that sits partially within a groove ofsecond body segment 20, spacer 42 or metal specimen 38, as applicable.Alternately, other known sealing means can be used.

Body spacer 43 can also be a part of the mating assembly. Body spacer 43can be a spacer and isolating member that circumscribes axial protrusion24 to separate metal specimen 38 from axial protrusion 24. In theexample of FIG. 4, where metal specimen 38 circumscribes a portion ofboth first body segment 18 and second body segment 20, body spacer 43can also circumscribe both first body segment 18 and second body segment20. As connection assembly 30 is tightened, body spacer 43 can maintaina separation between first body segment 18 and second body segment 20and can also prevent an inner diameter of metal specimen 38 fromcontacting an outer diameter of axial protrusion 24 of first bodysegment 18 and second body segment 20. Body spacer 43 can be sized sothat it does not interfere with the sealing properties of first bodyseal 44 and second body seal 46, while assisting to isolate thecomponents of monitoring tool 16.

The example embodiment of FIG. 8 can also include a mating assembly thatincludes one or more first body seal 44, one or more second body seal46, and body spacer 43. The mating assembly of FIG. 8 can furtherinclude spacer 42 that can be located at each end of metal specimen 38.Spacer 42 can circumscribe axial protrusion 24 and separate metalspecimen 38 from first body segment 18 and second body segment 20.Spacers 42 together with annular shoulder 26 and end 40 can act torestrict axial movement of metal specimen 38 relative to first bodysegment 18 and second body segment 20 when first body segment 18 andsecond body segment 20 are secured together.

Main body seal 48 can be located between first body segment 18 andsecond body segment 20. Main body seal 48 can be a ring shaped memberthat circumscribes axial protrusion 24. Main body seal can seal betweenfirst body segment 18 and second body segment 20 to prevent fluids frompassing between first body segment 18 and second body segment 20. Eachof the first body seal 44, second body seal 46, and main body seal 48can be formed of high temp non-metallic sealing materials.

Looking at FIG. 8, monitoring tool 16 can further include outerconnection 50. Outer connection 50 can be a part of first body segment18, second body segment 20, or both first body segment 18 and secondbody segment 20. Outer connection 50 can be used for connectingmonitoring tool 16 to intervention member 52 (FIG. 1) during deploymentor retrieval of monitoring tool 16. Outer connection 50 can be a maletype connector, a female type connector, or other style of connectioncommonly known for connecting tools to suspension members. In theexample of FIG. 2, intervention member 52 can be connected to monitoringtool 16 with a latching mechanism, threaded connection, or other knownmethod commonly used for downhole tools.

Intervention member 52 can extend downhole into wellbore 12 and canraise and lower monitoring tool 16 within subterranean well 10 andposition monitoring tool 16 within wellbore 12 at a predeterminedlocation and depth. Intervention member 52 can be, for example, a gaugehanger. Intervention member 52 can have gripping members 53 that can bein a retracted position when lowered into wellbore 12 and that canexpand radially outward and grip an inner diameter surface of wellbore12 when monitoring tool 16 has reached a predetermined location withinwellbore 12. Gripping members 53 can provide sufficient gripping forceto retain monitoring tool 16 within wellbore 12 without monitoring tool16 being attached to a wireline, coiled tubing, sucker rod, or otherinstallation string or wire. Intervention member 52 can include or beattached to a shock absorber that can protect monitoring tool 16 fromvibration of high velocity well flow within wellbore 12. Outerconnection 50 will match a connection required to mate interventionmember 52 or a shock absorber to monitoring tool 16. Intervention member52 can include a fishing neck to allow for retrieval or fishing, ifrequired. Outer connection 50 can also be used to connect monitoringtool 16 to one or more additional monitoring tools 16 or to anotherdownhole tool or tool string component.

In an example of operation, in order to monitor conditions withinsubterranean well 10 a selected metal specimen 38 can be measured todetermine the weight of metal specimen 38. Metal specimen 38 can also bemeasured to determine a shape or profile of metal specimen 38. Themeasurements can be performed, for example, by optical means such aswhite light interferometry.

Metal specimen 38 can then be placed around one of first body segment 18or second body segment 20. First body segment 18 can be releasablysecured to second body segment 20. As an example, axial protrusion 24can be threaded into inner recess 28 and set screw 36 can be inserted toextend from second body segment 20 to first body segment 18.Alternately, retaining member 31 can extend through first body segment18 and second body segment 20 to secure first body segment 18 to secondbody segment 20.

Intervention member 52 can be attached to outer connection 50. Incertain embodiments, additional monitoring tools 16 can be suspendedfrom intervention member 52 and the monitoring tools 16 can containmetal specimens 38 with different compositions so that conditions in thewellbore 12 can be measured using a variety of materials. Interventionmember 52 can be used to lower monitoring tool 16, as well as anyadditional members attached to monitoring tool 16, into wellbore 12.Monitoring tool 16 can be lowered to a predetermined location and depth.Monitoring tool 16 can be positioned with in a flow of fluids throughsubterranean well 10 at a predetermined location so that the outerdiameter surface of metal specimen 38 is located in a direct undisturbedflow of the fluids through subterranean well 10. Gripping members 53 canexpand radially outward and grip an inner diameter surface of wellbore12 to retain monitoring tool 16 at the predetermined location withinwellbore 12.

After a predetermined amount of time has passed, intervention member 52can be used to raise monitoring tool 16 out of subterranean well 10. Setscrew 36 can be removed and one of first body segment 18 and second bodysegment 20 can be rotated relative to the other so that axial protrusion24 is unthreaded from inner recess 28. Metal specimen 38 can beseparated from axial protrusion 24 and re-measured. Scale and depositanalysis can be performed on the un-cleaned metal specimen 38 using forexample, energy-dispersive X-ray spectroscopy (EDX), energy dispersiveX-ray fluorescence (EDF), powder X-ray diffraction (XRD), or other knownmeans. Metal specimen 38 can then be cleaned and measured once again.During each of these measurements, a weight and profile of metalspecimen 38 can be determined. The corrosion treatment program and otherwell optimization decisions relating to subterranean well 10 can then beadjusted, optimized, and improved based on the measurements of metalspecimen 38.

Embodiments of the disclosure described herein, therefore, are welladapted to carry out the objects and attain the ends and advantagesmentioned, as well as others inherent therein. While a presentlypreferred embodiment of the disclosure has been given for purposes ofdisclosure, numerous changes exist in the details of procedures foraccomplishing the desired results. These and other similar modificationswill readily suggest themselves to those skilled in the art, and areintended to be encompassed within the spirit of the present disclosureand the scope of the appended claims.

What is claimed is:
 1. A system for monitoring conditions within asubterranean well, the system comprising: a monitoring tool having: afirst body segment releasably secured to a second body segment, thefirst body segment having an axial protrusion with a reduced outerdiameter; a metal specimen circumscribing the axial protrusion so thatan outer diameter surface of the metal specimen defines an outerdiameter of the monitoring tool; a spacer member located between themetal specimen and the axial protrusion, the spacer member beingnon-metallic and electrically isolating the metal specimen from theaxial protrusion, where the spacer member is a solid ring shaped memberwith a consistent inner diameter and a consistent outer diameter andfree of openings through a sidewall of the spacer member, and isremovable from both the first body segment and the second body segmentand operable to slide over an end of the axial protrusion and bepositioned in any radial orientation about the axial protrusion; amating assembly located at each end of the metal specimen and separatingthe metal specimen from the first body segment and from the second bodysegment, where axial end faces of the spacer member directly contact oneof the mating assemblies; and an outer connection in one of the firstbody segment and the second body segment; and an intervention memberconnected to the outer connection, the intervention member having agripping member moveable between a retracted position and an extendedposition, wherein when the gripping member is in the extended position,the intervention member is operable to suspend the monitoring toolwithin the subterranean well.
 2. The system in accordance with claim 1,wherein the outer diameter surface of the metal specimen is located in adirect undisturbed flow of fluids through the subterranean well when themonitoring tool is lowered within the subterranean well.
 3. The systemin accordance with claim 1, further including the mating assemblyisolating the metal specimen from direct contact with the first bodysegment and the second body segment.
 4. The system in accordance withclaim 3, wherein the mating assembly is formed of a non-metallic andelectrically isolating material.
 5. A method for monitoring conditionswithin a subterranean well, the method comprising: providing the systemof claim 1; and lowering the monitoring tool into the subterranean wellwith the intervention member.
 6. The method in accordance with claim 5,further comprising before lowering the monitoring tool into thesubterranean well with the intervention member, measuring at least oneof a weight and profile of the metal specimen.
 7. The method inaccordance with claim 5, further comprising raising the monitoring toolout of the subterranean well with the intervention member and measuringat least one of a weight and profile of the metal specimen.
 8. Themethod in accordance with claim 5, further comprising raising themonitoring tool out of the subterranean well with the interventionmember and measuring a feature of the metal specimen, then optimizing atreatment of the subterranean well based on the measurement of thefeature, the treatment being one of a scale treatment or a corrosiontreatment.
 9. The method in accordance with claim 5, further comprisinglocating the monitoring tool in a flow of fluids through thesubterranean well so that the outer diameter surface of the metalspecimen is located in a direct undisturbed flow of fluids through thesubterranean well.
 10. The method in accordance with claim 5, furthercomprising moving the gripping member of the intervention member to theextended position so that the gripping member engages an inner diametersurface of the subterranean well.
 11. The method in accordance withclaim 5, further comprising securing one or more additional monitoringtools to the outer connection before lowering the monitoring tool intothe subterranean well.
 12. The method in accordance with claim 11,wherein a composition of the metal specimen of each monitoring tool isdifferent from the composition of the metal specimen of other monitoringtools.